Apparatus and methods for powering an electrical device associated with an aircraft rotor

ABSTRACT

Apparatus and methods for generating electrical power for powering a device associated with a bladed rotor driven by a gas turbine engine of an aircraft are disclosed. The apparatus includes a rotor shaft coupled the bladed rotor of the aircraft and driven by a turbine shaft of the engine via a speed-reducing gear train. A speed-augmenting power transfer device has an input coupled to the rotor shaft and an output for outputting a rotation speed higher than a rotation speed of the rotor shaft received at the input of the speed-augmenting power transfer device. An electric generator disposed in a hub of the bladed rotor is coupled to the output of the speed-augmenting power transfer device and configured to generate electrical power for the device associated with the bladed rotor.

TECHNICAL FIELD

The application relates generally to aircraft engines and, more particularly, to powering electrical devices associated with aircraft rotors driven by such engines.

BACKGROUND OF THE ART

Prime mover rotors such as propellers of fixed-wing aircraft and main rotors of rotary-wing aircraft have associated equipment such as pitch control devices for adjusting the pitch of the blades of the rotors and also de-icing devices. Typically, hydraulic power from the engine oil is used for pitch control and electrical power can be used for de-icing. Hydraulic power can be relatively inefficient to generate since pumps must be sized for maximum demand and then bypassed for much of the flight cycle and hence can represent a parasitic loss. With respect to supplying electrical power to de-icing devices of a rotor, multiple slip rings and brushes can be necessary to transfer the de-icing power. Slip rings and brushes can be prone to wear and require periodic maintenance.

Improvement is therefore desirable.

SUMMARY

In one aspect, the disclosure describes an apparatus for generating electrical power for powering a device associated with a rotor driven by a gas turbine engine of an aircraft. The apparatus comprises: a rotor shaft configured to be coupled to the bladed rotor of the aircraft and to be driven by a turbine shaft of the engine via a speed-reducing power transfer device; a speed-augmenting power transfer device having an input coupled to the rotor shaft and an output for outputting a rotation speed higher than a rotation speed of the rotor shaft received at the input of the speed-augmenting power transfer device; and an electric generator coupled to the output of the speed-augmenting gear train and configured be disposed inside a hub of the bladed rotor and to generate electrical power for the device associated with the bladed rotor.

In another aspect, the disclosure describes an aircraft engine. The engine comprises: a bladed rotor comprising a hub and an electrical device configured to carry out a function associated with the rotor; a rotor shaft coupled to the bladed rotor, the rotor shaft being coupled to a turbine shaft of the engine via a speed-reducing power transfer device; a speed-augmenting power transfer device having an input coupled to the rotor shaft and an output for outputting a rotation speed higher than a rotation speed of the rotor shaft received at the input of the speed-augmenting power transfer device; and an electric generator disposed in the hub of the bladed rotor and coupled to the output of the speed-augmenting power transfer device, the electric generator being electrically coupled to the electrical device of the rotor.

In a further aspect, there is provided a method of generating electrical power for powering an electrical device for carrying out a function associated with a rotor driven by a gas turbine engine. The method comprises: receiving input rotational motion from a rotor shaft driving the bladed rotor; augmenting an input rotation speed of the input rotational motion to produce an output rotational motion having an output rotation speed higher than the input rotation speed; generating, in a hub of the bladed rotor, electrical power from the output rotational motion at the output rotation speed; and delivering the electrical power to the electrical device associated with the bladed rotor.

DESCRIPTION OF THE DRAWINGS

Reference is now made to the accompanying figures in which:

FIG. 1 is a schematic partial cross-sectional view of an exemplary aircraft gas turbine engine for driving a rotor;

FIG. 2 is an axial cross-sectional view of an exemplary speed-augmenting power transfer device according to a first embodiment for driving a generator for powering an electrical device associated with the rotor of FIG. 1;

FIG. 3 is a schematic transverse cross-sectional view of a first stage of the speed-augmenting power transfer device of FIG. 2 taken along line 3-3 of FIG. 2;

FIG. 4 is a schematic transverse cross-sectional view of a second stage of the speed-augmenting power transfer device of FIG. 2 taken along line 4-4 of FIG. 2;

FIG. 5 is an axial cross-sectional view of another exemplary speed-augmenting power transfer device according to a second embodiment for driving the generator for powering the electrical device associated with the rotor of FIG. 1; and

FIG. 6 is a flow chart of an exemplary method of generating electrical power for powering the electrical device using the speed-augmenting power transfer device of either FIG. 2 or FIG. 5.

DETAILED DESCRIPTION

FIG. 1 illustrates an aircraft gas turbine engine 10, generally comprising in serial flow communication a bladed rotor 12 providing a prime-mover for the aircraft, in this case in the form of a propeller through which ambient air is propelled, a compressor section 14 for pressurizing ingested air, a combustor 16 in which the compressed air is mixed with fuel and ignited for generating an annular stream of hot combustion gases, and a turbine section 18 for extracting energy from the combustion gases. Bladed rotor 12 may be any suitable prime mover, for example, a propeller of a fixed-wing aircraft, a main (or tail) rotor of a rotary-wing aircraft such as a helicopter (not shown), or a fan of a turbofan engine (not shown).

In the exemplary embodiment shown, a rotor shaft 19 drives the rotor 12. The rotor shaft 19 is entrained by the turbine section 18 via a power turbine shaft 15 and a speed-reducing power transfer device such as, for example, speed-reducing gear train 17 disposed in a housing 13 and between the turbine shaft 15 and the rotor shaft 19. The speed-reducing gear train 17 reduces a rotation speed from the turbine shaft 15 into a rotation speed suitable for the rotor 12. In the embodiment shown in FIG. 1, the rotor shaft 19 is disposed along an axis Al offset from an axis A2 of the turbine shaft 15. There could be, however, configurations of the engine 10 suitable for application of the present approach, for example where the axes A1 and A2 are substantially coaxial.

In addition to driving the rotor 12, the rotation of the rotor shaft 19 may also be used to generate electrical power for powering one or more electrical devices such as auxiliary systems/devices of engine 10 via a speed-augmenting power transfer device such as, for example, gear train 20 (shown in FIG. 2) coupled to a generator 24. In other embodiments (not depicted), any suitable speed-augmenting power transfer devices (e.g., hydraulic transmission), or combination of devices may be used. In some embodiments, auxiliary devices may be electrically powered and may perform functions associated with the rotor 12. Electrical power may be a more economical alternative to hydraulic power since it may simply be drawn only when required for actuation. Examples of auxiliary devices may include a rotor blade de-icing system 64 and a rotor pitch control system 65. Such devices associated with the rotor 12 may be disposed inside or on rotor 12 and accordingly may be considered part of rotor 12.

Electrically-powered devices that may be disposed within the rotor 12 may include a blade pitch control system 65 and/or a de-icing system 64. During operation, ice may form on propeller blades and alter the aerodynamic characteristics of each blade. Ice formation on the propeller blades may also affect the propulsion characteristics of the engine 10. Commonly, the de-icing system 64 is incorporated into the propeller blades to maintain the aerodynamic characteristics of the propeller blades and such designs are known in the art. Generally, the de-icing systems 64 use electric power to function. Such power can be supplied by the generator 24.

Restarting the engine 10 during flight may require a power source to drive the turbine section 18 to a minimum rotational speed necessary for the compressor section 14 to generate pressure and flow conditions necessary to sustain combustion in the combustor 16. The systems described herein may allow the engine 10 to be self-restarting, thereby eliminating bulking auxiliary systems or reliance on a second engine or an auxiliary power unit. Electric power for restarting the engine 10 may be provided by the generator 24 when the rotor 12 is windmilling. The electric power produced while the rotor 12 is windmilling can be used to drive an electric motor, the electric motor causing the turbine section 18 to accelerate to speeds necessary to sustain combustion within the combustor 16. Once combustion is sustained, the exhaust gases expand through and further accelerate the turbine section 18 to normal operating conditions.

Ram air turbine (RAT) systems may provide emergency power to an aircraft during an engine failure or other electrical failure. RAT systems function by automatically extending a small turbine from the aircraft during an engine failure. The turbine drives a generator that provides electric power to critical aircraft systems. In a manner similar to restarting the engine 10, the present systems can function as a RAT system. During an electrical failure where no power may be available to the airframe, electric power from the generator 24 or from an auxiliary power connection may power an actuation system to position propeller blades for RAT operation. In this configuration, the power generation unit may supply electric power to critical aircraft systems during situations the engine 10 cannot be restarted.

The speed-augmenting gear train 20 is coupled to the rotor shaft 19 at one end (input) and to an output shaft 22 (shown in FIG. 2) at another end (output). The output shaft 22 rotates under the influence of the speed-augmenting gear train 20 at a rotation speed higher than that of the rotor shaft 19. A differential of rotation speed between the rotor shaft 19 and the output shaft 22 is used by the electric generator 24 (shown schematically) to generate power for the one or more of electrical devices 64, 65 described above. The electrical generator 24 may comprise a first rotatable member 24 a coupled for rotation with the output (e.g., output shaft 22) of the speed-augmenting gear train 20 and a cooperating second rotatable member 24 b coupled for rotation with the rotor shaft 19. In a non-limiting embodiment, the generator 24 may comprise a permanent magnet generator where the first rotatable member 24 a comprises one or more magnets and the cooperating second rotatable member 24 b comprises one or more windings. In various embodiments, generator 24 may be disposed inside hub 25 of bladed rotor 12.

The electrical generator 24 may be part of a power generation unit (not shown) including an inductive coupling (not shown) and an auxiliary power connection (not shown). The inductive coupling may include windings, each attached to the rotor shaft 19 and the output shaft 22. The inductive coupling communicates signals between the rotor shaft 19 and the output shaft 22. For example, to transmit a signal from the rotor shaft 19 to the output shaft 22, an electric current or signal current is supplied to one of the windings through cables (not shown) which may run through the associated the rotor shaft 19/output shaft 22. The signal current within the winding generates a magnetic field that interacts with the other winding to create a signal voltage therebetween. The inductive coupling may be electrically connected to a controller programmed to perform a function that corresponds to the signal voltage from the winding. The signal current can be varied in several ways for the purpose of transmitting commands to the controller. For example, the signal current can have a variable frequency or voltage, the changes in frequency or voltage causing corresponding changes in the signal voltage in the winding. The controller may be programmed to perform a command corresponding to frequency or voltage changes from the signal current.

The auxiliary power connection may include at least one slip ring and two or more electrical brushes connected to the rotor shaft 19 and the output shaft 22. The auxiliary power connection receives or transits electrical power through cabling that is routed through the output shaft 22 (e.g. passages 60, 61 described below). If multiple electrical circuits are required, additional slip-ring and brushes combinations can be added to auxiliary power connection. The auxiliary power connection can function as a backup system in the event of a failure of power unit by supplying electric power into the rotor 12. In this instance, electric power can be supplied through cabling routed through the output shaft 22 to the brushes . At least one slip-ring can receive the electric power from brushes and transmit the power to an actuation system where it can be used to change the pitch of rotor 12.

The speed-augmenting gear train 20 may be designed to be disposed at or adjacent either end 19 a, 19 b of the rotor shaft 19. In a first embodiment, the speed-augmenting gear train 20 is disposed at the end 19 a of the rotor shaft 19 (see FIGS. 2 to 4), and in a second embodiment, the speed-augmenting gear train 120 (see FIG. 5) is disposed at the end 19 b of the rotor shaft 19 inside the hub 25 of the rotor 12. The respective positions of the speed-augmenting gear trains 20, 120 are indicated by stippled lines in FIG. 1. End 19 a of the rotor shaft 19 may be relatively distal from rotor 12 and end 19 b of the rotor shaft 19 may be relatively proximal to rotor 12. The first or second embodiment of the speed-augmenting gear train 20, 120 may be chosen depending on a type and/or configuration of the engine 10. Some engines may even accommodate the two embodiments of the speed-augmenting gear train 20, 120.

The speed-augmenting gear train 20, 120 or part of it may be designed to fit within the rotor shaft 19, so that the output shaft 22 may be disposed inside the rotor shaft 19, and the electric generator 24 may be disposed between the rotor shaft 19 and the output shaft 22. Other designs of the speed-augmenting gear train 20, 120 may include the speed-augmenting gear train 20, 120 disposed outside of the rotor shaft 19, yet having the output shaft 22 substantially coaxial with the rotor shaft 19. Although a particular engine is shown in FIG. 1 in association with the speed-augmenting gear trains 20, 120, it is contemplated that the assembly of the speed-augmenting gear train 20, 120 and electric generator 24 for providing power to the auxiliary systems may be adapted to any suitable engine configuration.

Turning now to FIGS. 2 to 4, the speed-augmenting gear train 20 is shown in the first embodiment disposed at the end 19 a of the rotor shaft 19.

The speed-augmenting gear train 20 is contained in a gearbox housing 26 bolted to a flange 27 of the housing 13 of the speed-reducing gear train 17 at the end 19 a of the rotor shaft 19. The speed-augmenting gear train 20 is, in a non-limiting embodiment, a epicyclic two-stage gear train. The speed-augmenting gear train 20 has a first stage 28 a augmenting the rotation speed of the output shaft 22 relative to the rotor shaft 19, as well as changing a direction of rotation of the output shaft 22 relative to the rotor shaft 19. By changing the direction of rotation of the output shaft 22 relative to the rotor shaft 19, the output shaft 22 is counter-rotating shaft, which increases relative rotation speed between the rotor shaft 19 and the output shaft 22. The speed-augmenting gear train 20 includes a second stage 28 b adding further to the rotation speed of the output shaft 22 relative to that of the rotor shaft 19.

Referring more specifically to FIG. 3, in this example the first stage 28 a is an epicyclic gear set comprising a ring gear 30 a, a sun gear 32 a disposed concentrically to the ring gear 30 a and three planet gears 34 a disposed between the ring gear 30 a and the sun gear 32 a. The first stage 28 a could have one, two or more than three planet gears 34 a. The first stage 28 a gear set has a star arrangement where a carrier 36 a is fixed (i.e., grounded) to the stationary structure of engine 10 and accordingly the planet gears 34 a behave as stars and do not revolve around the sun gear 32 a.

The ring gear 30 a is fixedly connected to the rotor shaft 19, such that the rotor shaft 19 entrains the ring gear 30 a in rotation. The planet gears 34 a are disposed on the fixed carrier 36 a (shown in FIG. 2) between the ring gear 30 a and the sun gear 32 a. The carrier 36 a is attached to the housing 13 of the speed-reducing gear train 17 via connector 37 (shown in FIG. 2). The carrier 36 a provides a structural frame to position the planet gears 34 a circumferentially spaced apart relative to each other on a circle C1 which is concentric relative to the sun gear 32 a. The planet gears 34 a are meshed with the ring gear 30 a and with the sun gear 32 a such that rotation of the ring gear 30 a entrains rotation of the planet gears 34 a, which in turn entrains rotation of the sun gear 32 a. Arrow 42 represents rotation of the sun gear 32 a, arrow 44 represents rotation of the planet gears 34 a, and arrow 46 represents rotation of the ring gear 30 a. The arrow 46 is in a direction opposite to the arrow 42.

Referring to FIG. 4, in this example the second stage 28 b is another epicyclic get set including a ring gear 30 b, a sun gear 32 b disposed concentrically to the ring gear 30 b and three movable planet gears 34 b disposed between the ring gear 30 b and the sun gear 32 b. The second stage 28 b has a planetary arrangement where the ring gear 30 b is fixed (i.e., grounded) to stationary structure of engine 10. The second stage 28 b has a similar ring gear 30 b, sun gear 32 b and planet gears 34 b to the first stage 28 a, but rotation of the gears relative to each other is different than in the first stage 28 a. In the second stage 28 b, the ring gear 30 a is fixedly connected to the housing 13 of the speed-reducing gear train 17, while the sun gear 32 b is fixedly connected to output shaft 22, such that the sun gear 32 b entrains the output shaft 22 in rotation. The second stage 28 b could have one or more planet gears 34 b. The second stage 28 b could also have a different number of planet gears 34 b relative to the first stage 28 a.

The planet gears 34 b are disposed on a movable carrier 36 b (shown in FIG. 2) disposed between the ring gear 30 b and the sun gear 32 b. The planet gears 34 b move along a circle C2 in a direction (arrow 48) opposite to that of the sun gear 32 a of the first stage 28 a, so that the planet gears 34 b revolve around the sun gear 32 b. The carrier 36 b of the second stage 28 b is engaged with the sun gear 32 a of the first stage 28 a, so that the carrier 36 b is entrained in rotation by the sun gear 32 a via link 35. Similarly to the carrier 36 a, the carrier 36 b keeps the planet gears 34 b circumferentially spaced relative to each other around the sun gear 32 b. The planet gears 34 b are meshed with the sun gear 32 b such that rotation of the planet gears 34 b (arrow 50) entrains a rotation of the sun gear 32 b (arrow 52). The rotation of the sun gear 32 b induced by the planet gears 34 b is in a direction opposite to that of the planet gears 34 b. The rotation of the sun gear 32 b is thus in a direction opposite that the ring gear 30 a of the first stage 28 a thereby providing the counter-rotation of the output shaft 22 relative to the rotor shaft 19.

in use, when the engine 10 is running, the rotor shaft 19 drives the ring gear 30 a in rotation, and the speed-augmenting gear train 20 rotates the output shaft 22 fixed to the sun gear 32 b in a direction opposite to that of the rotor shaft 19 and with a higher number of revolutions per minutes. Any suitable speed-augmentation ratio may be provided. in this example, a ratio of between about 12:1 and about 17:1 may be achieved using the above speed-augmenting gear train 20. In one embodiment, a speed-augmentation ratio of about 16:1 may be achieved. In various embodiments, the first stage 28 a and the second stage 28 b may provide substantially the same or different speed-augmentation ratios. The output shaft 22 extends within the hub 25 to reach the electric generator 24 which exploits the difference in rotation between the output shaft 22 and the rotor shaft 19.

Although the first stage 28 a is shown herein to have the fixed carrier 36 a and the second stage 28 b to have the movable carrier 36 b, it is contemplated that the first stage 28 a could have the movable carrier 36 b and the second stage 28 b could have the fixed carrier 36 a.

Turning now to FIG. 5, the speed-augmenting gear train 120 is shown in the second embodiment disposed at or adjacent to the end 19 b of the rotor shaft 19 inside the hub 25 of the rotor 12.

The speed-augmenting gear train 120 has elements common to the speed-augmenting gear train 20. These elements will not be described in details herein again.

The speed-augmenting gear train 120 includes first and second stages 128 a, 128 b similar to the first and second stages 28 a, 28 b. The first stage 128 a is an epicyclic gear set having a star arrangement with a carrier 136 a fixed to the housing 13 of the speed-reducing gear train 17 via shaft 54 running through the rotor shaft 19. The second stage 128 b is an epicyclic gear set having a planetary arrangement with a movable carrier 136 b. The carrier 136 b is moved by its connection to a sun gear 132 a of the first stage 128 a similarly to the speed-augmenting gear train 20. An output shaft 122 is fixedly connected to a sun gear 132 b of the second stage 128 b and rotates with it. The output shaft 122 extends within the hub 25 to reach the electric generator 24.

The output shaft 22 and the speed-augmenting gear train 20, 120 may include stationary (non-rotating) through passages 60, 61 respectively. The passages 60, 61 may permit routing of one or more electrical wires between electrical components that may be disposed within the rotor 12 and electrical components disposed away from the rotor 12. These passages 60, 61 may be disposed within the rotor shaft 19 which may also comprise a hollow geometry providing a through passage in communication with through passages 60, 61.

Secondary/emergency power for such electrically-powered and rotor-mounted devices may be provided via conductors routed through passages 60, 61 and suitable slip rings. The through passages 60, 61 may also provide an independent route for hydraulic power to an actuator or a mechanical linkage in addition to or independently from the electric wires described above. The electrical path may also be used for communication with inductive coupling (rotating transformer) instead of slip rings and brushes, as described above. As best shown in FIG. 2, an oil-retaining shaft 62 may be provided between the rotor shaft 19 and the output shaft 22 to restrain oil within the rotor shaft 19.

In various embodiments, the above described power generating apparatus may provide a compact generator 24 coaxial with the rotor shaft 19 and disposed inside hub 25 meeting the power demands of the auxiliary systems (e.g., blade pitch control system 65 and/or a de-icing system 64).

The amount of power extracted from a rotating shaft (e.g. output shaft 22) via generator 24 can depend on a tangential velocity of this shaft relative to the tangential velocity of a reference structure (e.g. rotor shaft 19). To achieve the tangential velocity needed to produce the power required by the auxiliary systems, one needs to have either a large diameter when the shaft rotates at a low rpm, or a small diameter when the shaft rotates at a high rpm. Since the engine shaft 19 rotates at a relatively low rpm (relative to the required power for the auxiliary systems), the speed-augmenting gear trains 20, 120 can be used to produce a high rpm and thereby permit adequate power generation within a relatively small space.

The speed-augmenting gear train 20, 120 may allow to generate the required power to the auxiliary systems while having a compact design which may be fitted within the rotor shaft 19 and/or hub 25. The speed-augmenting gear train 20, 120 may provide a lighter alternative to redesigning the speed-reducing gear train 17 for obtaining same electrical output. The above described power generating apparatus may be adapted to engines having coaxial engine shafts 19 and turbines shafts 15, as well as engines having offset engine shafts 19 and turbines shafts 15.

The substantial concentricity and coaxiality of the rotor shaft 19 and the speed augmenting gear train 20, 120 may optionally provide a through path which may be used for communication, emergency power, and the like. Power and data transmission requirements across the speed-augmenting gear train 20, 120 may be minimised. The apparatus may be applied to other suitable types of aircraft and in other suitable applications such as pitch control systems for wind turbines.

Turning now to FIG. 6, a method 70 of generating electrical power for powering an electrical device (e.g., de-icing system 64 and the pitch control system 65) for carrying out a function associated with the rotor 12 driven by the gas turbine engine 10 will be described. Method 70 may be performed using the apparatus and devices disclosed herein. Method 70 may comprise: receiving input rotational motion from the rotor shaft 19 driving the rotor 12 (see block 72); augmenting an input rotation speed of the input rotational motion to produce an output rotational motion having an output rotation speed higher than the input rotation speed (see block 74); generating electrical power from the output rotational motion at the output speed (see block 76); and delivering the electrical power to the electrical device 64, 65 associated with the rotor 12.

In various embodiments, the output rotational motion is in a direction opposite that of the input rotational motion.

The above description is meant to be exemplary only, and one skilled in the art will recognize that changes may be made to the embodiments described without departing from the scope of the invention disclosed. For example, the apparatus, devices and methods described herein could be used in helicopters. Still other modifications which fall within the scope of the present invention will be apparent to those skilled in the art, in light of a review of this disclosure, and such modifications are intended to fall within the appended claims. 

1.-18. (canceled)
 19. An apparatus for powering an electrically-powered and rotor-mounted device of a bladed rotor driven by a gas turbine engine of an aircraft, the apparatus comprising: a rotor shaft configured to be coupled to the bladed rotor and to be driven by a turbine shaft of the engine; a speed-augmenting power transfer device having an input coupled to the rotor shaft and an output for outputting a rotation speed higher than a rotation speed of the rotor shaft received at the input of the speed-augmenting power transfer device; an electric generator coupled to the output of the speed-augmenting power transfer device and configured be disposed inside a hub of the bladed rotor and to supply electrical power to the electrically-powered and rotor-mounted device of the bladed rotor; and an electrical conductor associated with the operation of the electrically-powered and rotor-mounted device of the bladed rotor, the electrical conductor being routed through a passage defined through the speed-augmenting power transfer device.
 20. The apparatus as defined in claim 19, wherein the electrical conductor is routed from a location within the hub of the bladed rotor to a location away from the bladed rotor.
 21. The apparatus as defined in claim 19, wherein the electrical conductor comprises an electrical wire configured to supply emergency power to the electrically-powered and rotor-mounted device of the bladed rotor.
 22. The apparatus as defined in claim 19, wherein the electrical conductor is also routed through the rotor shaft.
 23. The apparatus as defined in claim 19, wherein the electrically-powered and rotor-mounted device of the bladed rotor is a blade pitch control system.
 24. The apparatus as defined in claim 19, wherein the electrically-powered and rotor-mounted device of the bladed rotor is a de-icing system.
 25. The apparatus as defined in claim 19, wherein hydraulic power is routed through the passage.
 26. The apparatus as defined in claim 19, wherein a mechanical linkage is routed through the passage.
 27. The apparatus of claim 19, wherein the output of the speed-augmenting power transfer device outputs rotational motion in a direction opposite that of the rotor shaft.
 28. The apparatus of claim 19, wherein the output of the speed-augmenting power transfer device and the rotor shaft are substantially coaxial.
 29. An aircraft engine comprising: a bladed rotor comprising a hub and an electrically-powered and rotor-mounted device configured to carry out a function associated with the bladed rotor; a rotor shaft coupled to drive the bladed rotor, the rotor shaft being coupled to be driven by a turbine shaft of the engine; a speed-augmenting power transfer device having an input coupled to the rotor shaft and an output for outputting a rotation speed higher than a rotation speed of the rotor shaft received at the input of the speed-augmenting power transfer device; an electric generator coupled to the output of the speed-augmenting power transfer device and disposed inside the hub of the bladed rotor, the electric generator being configured to supply electrical power to the electrically-powered and rotor-mounted device of the bladed rotor; and an electrical conductor associated with the operation of the electrically-powered and rotor-mounted device of the bladed rotor, the electrical conductor being routed through a passage defined through the speed-augmenting power transfer device.
 30. The aircraft engine as defined in claim 29, wherein the rotor shaft is coupled to be driven by the turbine shaft of the engine via a speed-reducing power transfer device.
 31. The aircraft engine as defined in claim 29, wherein the electrical conductor is routed from a location within the hub of the bladed rotor to a location away from the bladed rotor.
 32. The aircraft engine as defined in claim 29, wherein the electrical conductor comprises an electrical wire configured to supply emergency power to the electrically-powered and rotor-mounted device of the bladed rotor.
 33. The aircraft engine as defined in claim 29, wherein the electrical conductor is also routed through the rotor shaft.
 34. The aircraft engine as defined in claim 29, wherein the electrically-powered and rotor-mounted device of the bladed rotor is a blade pitch control system.
 35. The aircraft engine as defined in claim 29, wherein the electrically-powered and rotor-mounted device of the bladed rotor is a de-icing system.
 36. The aircraft engine as defined in claim 29, wherein hydraulic power is routed through the passage.
 37. The aircraft engine as defined in claim 29, wherein a mechanical linkage is routed through the passage.
 38. The aircraft engine of claim 29, wherein the output of the speed-augmenting power transfer device and the rotor shaft are substantially coaxial. 